JP2002538739A - Method and related apparatus for communication packet data in a wireless communication system - Google Patents

Abstract

SUMMARY A method associated with an apparatus for a wireless communication system (10), such as cellular, that facilitates communication between a mobile station (12) and a network infrastructure (48). When the mobile station (12) registers with the communication system (10), a dedicated reverse link channel (34) is allocated to facilitate communication of packet data between the mobile station (12) and the network infrastructure (48). . By providing a dedicated channel, the mobile station (12) is operatively connected to the network infrastructure, similar to a hard-wired connection of a computer in a local area network.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[Industrial applications]

The present invention relates to communication of packet data in a wireless communication system such as a CDMA2000 cellular communication system. More particularly, the present invention relates to a method and related apparatus for transmitting packets and other data between a mobile station and a network when a wireless interface is formed therebetween. By implementing an embodiment of the present invention, a dedicated reverse link (functionally connecting a mobile station to a network infrastructure (industrial infrastructure) in a manner similar to the hardware connection of a computer in a LAN (local area network)) Reverse link) channel is provided.

[0002]

[Prior art]

Advances in digital telephony technology have enabled the development, implementation, and wider use of multi-user communication systems. In particular, the use of digital communication systems that utilize digital technology is useful because the communication capabilities of digital communication systems are generally higher than the capabilities of corresponding analog systems. Error correction of signals transmitted during operation of such a system can also be improved.

[0003] Cellular communication systems are typical of communication systems enabled as a result of these advances. The cellular communication system enables communication with the mobile station via a wireless channel, thereby forming a communication channel between the transmitting station and the receiving station without the need for a wire connection. Through the use of cellular radio systems, communication can be achieved even in places where the use of fixed or hard-wired connections is inconvenient or not feasible, such as in automobiles. Cellular communication systems are implemented using various communication technologies. CDMA (Code Division Multiple Access) cellular communication systems are typical communication systems implemented using code division techniques.

[0004] Several cellular communication systems provide for the transmission of packet data to and from mobile stations. The information to be transmitted is formatted into separate data packets, and once formatted, the packets are transmitted over a communication channel. In CDMA communication technology, for example, packet channels are allocated by allocating codes, whereby data packets are encoded. Once encoded, the packets are transmitted by the transmitting station.
Also, once received at the receiving station, those data packets are decoded.

[0005] While a circuit-switched channel can be formed to enable the communication of packet data between the mobile station and the network infrastructure, such assignments lose significant advantages of packet data communication. That is, when the information to be conveyed is formatted into multiple data packets, one shared channel may be used.
Information to be conveyed according to more than one data service or according to more than one pair of transmitting and receiving stations can share a single communication channel. The communication capability of communication in a wireless communication system can be increased by the shared characteristics of communication transmission in one shared channel, not in a circuit-switched channel.
Conventionally, packet data applications use SMS (Short Message Service) communication in, for example, a GSM (Pan European Digital Mobile Telephony) communication system or in an operating state where the mobile state can be implemented in a CDMA2000 system. Realized to run on a dedicated wireless channel.

[0006] Also, when such channels are allocated and distributed, a substantial amount of build-up and tear-down (decomposition) overhead is required to achieve them. Therefore, in addition to the communication capabilities limitations associated with allocating circuit-switched channels to carry packet data, the increased overhead associated with the distribution of circuit-switched channels is also problematic.

[0007] The increase in processing power has enabled the execution of new types of data services, such as multimedia services in which more than one type of communication is conveyed, both voice information and non-voice information.

[0008] The communication of two or more data services also raises particular problems that need to be resolved when the data service is to be realized over a wireless link.

A method for more efficiently transmitting packet data to achieve one or more services in a wireless communication system is therefore useful.

In light of this background information relating to the communication of wireless communication systems, significant improvements of the present invention become apparent.

[0011]

Summary of the Invention

The present invention therefore provides a method and associated apparatus for better realizing communication between a mobile station and a network infrastructure in a wireless communication system such as a cellular communication system.

When data is to be transmitted by the mobile station to the network infrastructure, a reverse link channel is allocated for transmission of such packet data. Since the dedicated channel is always assigned to the mobile station, packet data communication can be quickly and reliably realized in a highly reliable manner. The dedicated reverse link channel is
A mobile station is operatively connected to a network infrastructure in a manner similar to a hard wired connection of a computer in a local area network.

In one aspect of the invention, a physical layer is provided that includes a forward flow channel and a constantly assigned reverse flow channel. The forward flow channel is a broadcast forward link channel on which both paging system and control messages are broadcast in a point-to-multipoint manner. The always-assigned reverse flow channel is used for transmitting packet data in addition to transmitting pilot signals that carry registration and control messages. By defining these channels, the mobile station is, in effect, always connected to the network infrastructure.

[0014] Due to the always-allocated nature of the reverse flow channel and the data and messages transmitted thereon, those data and messages may be present even when the mobile station is not operating in an active call state. However, it is used by the network infrastructure for local positioning of mobile stations.

In another aspect of the invention, a new mobile station structure is provided. In addition to the improvements to the physical layer including the forward and reverse flow channels described above,
A packet data layer (PDL) is provided. PDL is layered between an IP (Internet Protocol) layer and a physical layer operable in a conventional manner to form datagrams formed from both header and payload information. PDL serves to break up datagrams into smaller units for transmission over the air interface on the reverse flow channel. I
The P layer leads to the top of the PDL, which in turn leads to a physical layer, such as a CDMA2000 physical layer.

In another aspect of the invention, a multitasking coordination is provided. That is, a multitasking entity is provided that probes each data service of a mobile station network infrastructure connection that is active or is operating nearby. In response to this investigation, channel assignments are made and the realization of data services is ensured in an efficient manner. A common forward channel is defined such that system load, cost information, and instantaneous assignment of mobile station specific resource information are broadcast.

In yet another aspect of the present invention, a layering scheme is provided that separates instantaneous network routing and channel resource information from data services, while also allowing data services to function at the required performance levels. it can. The data carriers are thereby separated from their associated applications.

In another aspect of the present invention, a method is provided for further optimizing the use of active packet data and IS-95B data bursts available in the proposed CDMA2000 system. User QoS (quality of service) requirements and system wireless communication capabilities will be maximized. Short message bursts are also allowed when the mobile station is operating in an intermediate state as well as when it is operating in an active and inactive state. A determination is made of the length of the user data burst or transaction, the delay allowed by the application, and the error or failure rate allowed by the application. A method is provided for transmitting data in response to such a determination.

Thus, through the operation of various embodiments of the present invention, packet data is transmitted from a mobile station of a wireless communication system to a network infrastructure in a more efficient manner.

In these and other aspects, therefore, there is provided a method and associated apparatus in a wireless communication system for transmitting packet data at a mobile station to a network infrastructure of the wireless communication system. A mobile station is registered with the network infrastructure at least when the mobile station is initially located in a predetermined registration zone defined by the wireless communication system. In response to this registration, a dedicated multipurpose reverse link channel is allocated for transmitting at least the packet data at the mobile station to the network infrastructure.

A more complete understanding of the present invention and its scope may be gleaned from the accompanying drawings, the presently preferred embodiments of the invention, and the appended claims, summarized below.

DETAILED DESCRIPTION OF THE INVENTION Referring first to FIG. A portion of the cellular communication system indicated generally by the numeral 10 provides wireless communication with a plurality of mobile stations exemplified by the mobile station 12. System 1
0 includes a plurality of spaced radio base stations located in a geographic area. This diagram is illustrative, and in a typical cellular communication system a number of radio base stations are located in a geographic area.

In the illustrated execution, three wireless base stations 14 are commonly arranged. Each of these radio base stations defines a cell 16. A cell is a part of a geographic area surrounded by a cellular communication system, within which communication between a radio base station defining such a cell and a mobile station can be realized. In general, a plurality of group cells 16 including a plurality of cells 16 which are a large number of cells together define a registration area. In the figure, two registration area portions separated by a boundary 18 are shown. At least when the mobile station passes from one registration area to another registration area, the mobile station is registered according to a registration procedure, thereby determining its location in the cellular communication system. Conventionally, a mobile station also registers when the mobile station is first turned on.

In the illustrated example where three sets of radio base stations are co-located, each radio base station defines a sector cell in a conventional manner. A plurality of groups including a plurality of wireless base stations 14 are connected to a BSC (base station controller) 20. BSC,
It serves to control the operation of the wireless base station connected to itself. A plurality of groups consisting of a plurality of BSCs are connected to an MSC (Mobile Switching Center) 22. MSC
Serves, among other things, to perform the exchange operation. MSC22 is GMS
It is connected to a PSTN (Public Telephone Switching Network) via a C (Gateway Mobile Switching Center) 26. The PSTN is connected to a plurality of communication stations such as the communication station 28.

In accordance with one embodiment of the present invention, a dedicated reverse link channel and forward link channel are formed between the mobile station and the network infrastructure, such as for packet data communications generated according to multimedia applications. Communication will be encouraged. Forward link channels are broadcast forward link point-to-multipoint (one-to-many)
Forming a channel, the reverse channel forming a continuous reverse link control channel. In one example implementation, the broadcast forward channel carries paging messages and also controls messages to mobile stations to control packet data communications. The continuous reverse link control channel also carries pilot signals, registration messages, and control messages in one example implementation. By defining these reverse and forward flow channels, mobile stations forming a link with a plurality of channels can be connected to a local area network (L).
It can be kept connected to the network infrastructure in a manner analogous to the hard-wired connections of computers in AN).

The communication system 10 is also shown in FIG. In FIG. 2, mobile station 1
2 is shown connected to the radio base station 14 via the reverse flow channel 34. The radio base station 14 is again shown connected to a base station controller 20, which further includes an MSC 2
2 are connected. Also in FIG. 2, the MSC 22 is shown connected to the GMSC 26, and the GMSC 26 is further connected to the PSTN 24. The connection of PSTN 24 to communication station 28 is also shown in this figure.

FIG. 2 further shows a VLR (Visitor Location Register) 36 located at or controlled by the MSC 22. In the conventional method, V
The LR 36 can communicate with an HLR (Home Location Register) 42 via the line 38 shown here. VLR 36 and HLR 42 operate in a conventional manner and maintain a record of the location of mobile station 123. In addition, during the execution of an embodiment of the present invention, the mobile station registers with the network infrastructure of the communication system when the mobile station is powered on and when the mobile station moves to a new registration area. I do. Through such a registration procedure, information relating to the mobile station is stored in the VLR 36. Also, in response to this registration, a reverse flow channel 34 is assigned to the mobile station. Also shown here is the forward flow channel forming the point-to-multipoint broadcast channel 44, on which multiple messages may be broadcast to multiple mobile stations, such as mobile station 12. become.

FIG. 3 shows the communication system 10. Here, parts of the system are shown from an application layer perspective. Also, the structure of the mobile station 12 and the network infrastructure, here designated 48, are shown in parallel for explanation. Applications 52, such as multimedia applications at the mobile station in addition to those in the network infrastructure, are also shown as layers at the mobile station and in the network infrastructure, respectively. These applications are executed on the TCP / UDP application 54 which is hierarchized on the IP layer 56. As shown, application data is passed between an application 52 and a TCP / UDP application layer 54. Data segments or user datagrams are TCP / UDP
It is passed between the application layer 54 and the IP layer 56.

The IP layer 56 runs on a new packet data layer (PDL) 58. The packet data layer multiplexes the IP process, provides transmission and reception windows for flow control over the broadcast interface, provides reliable communication between the mobile station 12 and the network infrastructure 48, and provides framing. That is, a frame header or a frame trailer is placed on the data. These functions are represented via a line 62 extending between the network 48 and the mobile station 12. As shown, datagrams are passed between the IP layer 56 and the packet data layer 58. The packet data layer defines a single layer, which is often called a conflict (collision, contention), redundant (redundant), missing (
It provides all the functions that previously needed to be realized by the set of entities that caused the (lost) action.

The frame of data formed by the packet data layer 58 is provided on the physical layer 64 to which the reverse flow channel 34 is allocated as described above. A forward flow channel 44 is also shown in the figure to extend at the physical layer level between the network infrastructure and the mobile station.

In operation, the application 52 creates IP source and destination addresses and ports, all of which form a socket to the TCP or UDP layer 54. Layer 54 forms the data into a plurality of segments and, if layer 54 is a UDP layer, into a plurality of user datagrams. These datagram segments are passed to the IP layer 56. At the IP layer, datagrams are formed. The datagram contains both source and destination addresses, and the datagram is subsequently
Passed to.

The packet data layer 58 breaks down the plurality of datagrams provided to it into a plurality of units, referred to herein as data frames. These frames of data are transmitted over a wireless interface formed between the mobile station and the network. The link destination is the IW for the mobile station that generated the data.
F, segments of data are numbered and transmitted according to conventional transmit / receive window rules. The operation of the packet data layer 58 provides a way to interface (combine) the IP layer and the physical layer (here, the physical layer of a CDMA2000 cellular communication system).

Because a dedicated reverse flow channel 34 is provided to facilitate the realization of communication between the mobile station and the network, the mobile station has a hard-wired connection formed between the computer and the local area network. In a similar manner, the device connection with the network is maintained.

By forming the reverse flow channel, the network infrastructure 48 has data that can be used to determine the location of a mobile station (even if the mobile station is not operating in a working call state). Will be provided. Also, through the implementation of an embodiment of the present invention, the reverse flow channel 34
Controlled by messages generated by the network infrastructure,
Power control channel, as transmitted on the forward flow channel to the mobile station. In this manner, forward flow channel 32 operates in a manner similar to that specified in the CDMA standard, ie, the FCCCH, except that forward flow channel 44 ensures the flow control characteristics and reliability of the packet data service. I do.

Also, since the forward and reverse flow channels 32 and 34 are continuous, the packet data layer 58 responds based on the exchange of frames of data (A
CK). If the error interface capacity is limited, flow control can be achieved by the network infrastructure through the PDL layer, for example, by simply establishing a zero link reception window. The packet data layer must assemble the received frame into a complete IP datagram before sending such data to the IP layer. In one run, the packet data layer is formed in one PPP run.

Thus, every time the mobile station is registered in the new registration zone, a dedicated extended reverse control channel of the power control type is provided to the mobile station. This reverse channel
It is useful for achieving multiplexing of services, reliability of packet data links and packet data flow control in CDMA cellular packet services. Geographic positioning, ie, determining the physical location of the mobile station, is also facilitated through continuous transmission of data on the reverse flow channel. Walsh coding, connected to the forward channel 44, which serves the purpose of controlling the reverse channel power of the signal generated by the mobile station, is necessary for packet data link reliability, packet data flow control, and multiplexing of services. It is also provided to complete the message exchange performed.

FIG. 4 illustrates a mobile station along with the channels over which data is transmitted during the implementation of another embodiment of the present invention. In this embodiment, the mobile station 12 can support a number of simultaneous data services as needed to implement a multimedia application. In one example implementation, the mobile station 12 can operate in the manner described above, and the reverse flow channel 34 (shown in FIG. 3) is allocated to facilitate communication. In another implementation, the mobile station 12 is used in a conventionally defined manner.

Here, mobile station 12 is shown to include a multi-task coordinator. The multi-task coordinator separates the plurality of data services, here represented by the first data service 74 and the second data service 76, from each other, and blocks the plurality of data services, here the Separation from the knowledge of the available network resources represented by 78 and the available radio resources represented here by blocks 82 and 84. As shown, network resources 78 include, for example, service option connections and routing table setup.

In the conventional method, a plurality of resources, such as resources 78 to 84, are released when the timer expires, in a manner similar to packet data disconnection in GPRS (General Packet Radio Service). The timer value is set according to a QoS (quality of service) request. The release of these resources is indicated in the network infrastructure, and an indication of this release is provided to the mobile station 12 via, for example, the forward flow channel 32 shown in FIG. These indications may also be provided to the mobile station via an IS-95 forward paging channel, represented here as the Common Packet Control Channel (CPCC). In one implementation, the mobile station 12 does not need a network origination, resource release message.

The multitask coordinator 72 has a common packet control channel (CPCC)
The periodic broadcast of the resource configuration field of the status message broadcast above keeps the resources allocated for the realization of the data services 74, 76 synchronized with the network infrastructure. The resource configuration field contains the status of the service option, among other things PPP, active set exi.
service options, such as stence), RF channel assignment, how the assigned RF channels should be used to implement the data service, ie, an indication of whether those channels should be used or observed in slot mode. Give the state.

The multitasking coordinator 72 receives an indication of the acceptable bit-bandwidth combination and the acceptable bit error rate (BER) of each data service 74, 76. In response to these requests, the multitasking coordinator 72 will respond to the joint request of all data services, here data services 74 and 76, by one
One or more trunks, ie, appropriately sized radio channels 82, 8
Request 4 pools. In one implementation, the requests made by the multitask coordinator are based on statistics and may be a function of the current load of the communication system.

An indication of the current load of the communication system, in one implementation, is indicated on the CPCC by a cost-per-bit-per-delay field in a status message. In response to the user's profile and the delay-per-bit-per-cost field that the multitasking coordinator 72 is aware of, a determination is made whether the multitasking coordinator has requested the allocation of resources to perform a particular communication service. You. This field increases significantly as the availability of resources available in the system becomes scarce. Also, the user profile can be indexed to determine whether the data service can be implemented based on the user profile.

In the implementation shown in FIG. 1, the data services 74, 76 do not know the state of the multiplex layer 88. The data service also determines which resources 74 to
I don't know if 84 is available. The multiplex layer 88 includes the data service 7
4. Map the incoming service requests generated by 4 and 76, along with available raw resources, and transmit the data to the extent that those resources are available to implement data services 74 and 76. Multiplex layer 88
The resulting delay is monitored by the multitask coordinator. If these delays reach a value greater than expected for the bandwidth obtained by the multitasking coordinator, this coordinator needs more channel resources depending on the user profile.

In one execution, the multitask coordinator operates the data service 7
4, at least one of the data services is active, or
When operating nearby, it communicates over a pure two-layer MS-network via a dedicated control channel. If neither of the services 74, 76 is transmitting or receiving data, the multitask coordinator 72 is simply informed of network activity (utilization) by monitoring the CPCC.

When the data transaction is a transaction generated by a mobile station,
The initial trunk request is sent from the mobile station to the network infrastructure using the Aloha method as specified in the IS-95 standard associated with the access channel. In another implementation, the first request is made by using the always assigned reverse flow channel 34 shown in FIG.

Thus, one embodiment of the present invention investigates the delay and throughput needs of all active or near-active services in a mobile station network connection, and also according to those needs, the mobile station A multitasking entity is provided that requests channel resources according to the user profile. The common forward channel, the CPCC, is used to allocate and release communication channels in addition to providing an indication of mobile station-specific instantaneous allocations of system load, cost information, and resources. You. The implementation illustrated in FIG. 4 also separates instantaneous network routing and channel information from data services, and further enables those data services to be implemented at the required performance levels in terms of delay, throughput, and cost. Things. This separates the means of transporting the data from the application, thus creating a scalable system.

FIG. 5 illustrates a method, generally designated by the numeral 92, of one embodiment of the present invention. The method facilitates communication of packet data between a mobile station of a wireless communication system and a network infrastructure. First, as indicated by block 94, the mobile station registers with the network infrastructure at least when it is first located in a predetermined registration zone defined by the wireless communication system.

Thereafter, as indicated by block 96, a dedicated multi-purpose reverse link channel for transmitting at least the mobile station generated information to the network infrastructure is allocated.

The above description is a preferred example for practicing the present invention, and the scope of the present invention need not be limited by this description. The scope of the invention is defined by the appended claims.

[Brief description of the drawings]

FIG. 1 illustrates a portion of a cellular communication system in which a preferred embodiment of the present invention may be implemented.

2 shows a functional block diagram of several parts of the network infrastructure of the cellular radio system shown in FIG.

FIG. 3 shows another functional block diagram of the communication system shown in FIG.

FIG. 4 shows a functional block diagram of a part of the cellular radio communication system shown in FIG. 1 according to another embodiment of the present invention.

FIG. 5 illustrates a method flow chart listing method steps of a method of operation of an embodiment of the present invention.

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Claims (21)

[Claims] 1. A method for facilitating the transmission of packet data between a network infrastructure of a wireless communication system and a mobile station, wherein at least the mobile station is initially located in a predetermined registration zone defined by the wireless communication system. Registering the mobile station with the network infrastructure, and allocating a dedicated multipurpose reverse link channel for transmitting at least information generated by the mobile station to the network infrastructure in response to the registration during the registration operation. A method comprising: 2. The method according to claim 1, wherein the predetermined wireless communication system defines a plurality of registration zones, and the registration operation is performed when the mobile station is assigned to a different one of the registration zones. The method comprising registering the mobile station each time it is located. 3. The method of claim 1 including the additional task of transmitting packet data from the mobile station to the network infrastructure on the dedicated multi-purpose reverse link channel allocated during the assignment operation. Method. 4. The method of claim 1, wherein the dedicated multi-purpose reverse channel is further allocated to carry a pilot signal, wherein the information generated by the mobile station includes a pilot signal, and the method comprises: The method comprising transmitting a pilot signal from the mobile station to the network infrastructure on the dedicated multipurpose reverse link channel. 5. The method of claim 1, wherein the dedicated multi-purpose reverse link channel is further allocated to carry control messages, wherein the information generated by the mobile station includes control information. The method comprises the additional task of transmitting control signals from the mobile station to the network infrastructure on the dedicated multipurpose reverse link channel. 6. The method of claim 1, further comprising: allocating a point-to-multipoint forward link channel, transmitting a control message from at least the network infrastructure to the mobile station. 7. The method according to claim 6, wherein the control message includes a power control command for controlling at least a power level at which packet data transmitted on the dedicated multipurpose reverse link channel is transmitted. The method. 8. The method of claim 1 including the additional task of determining the location of the mobile station in response to a signal carried on the dedicated multipurpose reverse link channel. 9. The method of claim 1, wherein the wireless communication system is a CD.
The method, comprising an MA communication system, wherein the dedicated multipurpose reverse link channel communication channel is an informally enhanced channel. 10. The method of claim 1, wherein the mobile station includes an IP (Internet Protocol) layer on which a datagram including header and payload information is formed, and wherein the method is formed at the IP layer. Datagram to PD
The method of claim 1, further comprising providing additional work to the L (packet data layer), wherein the PDL converts the datagram into portions of packet data for communicating over the dedicated multipurpose reverse link channel. 11. The method of claim 1, wherein the packet data is selectively transmitted to implement a first data service or at least a second data service, the method further comprising: And further comprising the step of coordinating the communication of the packet data to achieve the at least second data service via the dedicated multipurpose reverse link channel, respectively. 12. The method of claim 11, wherein the coordinating operation comprises examining a communication request to implement the first and at least the second data services. 13. The method of claim 12, wherein the coordinating operation is performed in the network infrastructure, the coordinating operation further comprising communicating a communication request from the mobile station to the network infrastructure on a dedicated control channel. The method further comprising: 14. The method of claim 13, including the additional task of allocating channel capacity in response to a survey performed during the surveying operation. 15. The method of claim 14, including the additional task of communicating the allocation of the channel capacity to the mobile station on a common forward channel. 16. The method of claim 1, wherein the mobile station is operable at least in an active state, a deactivated state, and an intermediate state, the method comprising: Determining the characteristics of the data to be transmitted, the method comprising the additional task of responsive to the characteristics of the data determined during the determining operation, selecting a state for transmitting the data to the mobile station. . 17. An apparatus for facilitating transmission of packet data from said mobile station to said network infrastructure in a wireless communication system enabling transmission of packet data between a network infrastructure of a wireless communication system and a mobile station, At least, when the mobile station is first positioned in a predetermined registration zone defined by a wireless communication system, a registration device that registers the mobile station with the network infrastructure, and a registration device that registers the mobile station in the registration device. A channel allocating device operable in response and allocating a dedicated multi-purpose reverse link channel for transmitting at least the information generated by the mobile station to the network infrastructure. 18. The apparatus according to claim 17, wherein the information generated by the mobile station comprises a pilot signal, and the dedicated multi-purpose reverse link channel allocated by the channel allocator further comprises a pilot signal and a control therein. The device for transmitting a message. 19. The apparatus according to claim 17, wherein the mobile station comprises an IP (Internet Protocol) layer on which a datagram including a header and payload information is formed, and the apparatus further comprises: the IP layer. A PDL coupled to receive the datagram formed by the PDL, the PDL converting the datagram into a plurality of portions of packet data for communicating over the dedicated multipurpose reverse link channel. The device. 20. The apparatus according to claim 17, wherein the mobile station is operable at least in an active state, an inactive state, and an intermediate state, wherein the apparatus further comprises: an interface between the mobile station and the network infrastructure. A decision device coupled to receive an indication of the characteristics of the data to be communicated between; selecting a state operable in response to a decision by the decision device to cause the mobile station to communicate data. A device, comprising: a selection device. 21. The method of claim 11, wherein the coordinating operation is further responsive to cost information associated with at least one of the first data service and the at least second data service. The method operable.